Near-field simulations of pellet ablation for disruptions mitigation in tokamaks

TL;DR

This study uses advanced numerical simulations to analyze neon pellet ablation in tokamak disruptions, focusing on atomic processes, magnetic effects, and validation against models, to improve disruption mitigation techniques.

Contribution

It introduces a next-generation pellet ablation code with detailed physics models and validates it against established theories, enhancing understanding of pellet behavior in magnetic fields.

Findings

Atomic processes significantly influence ablation rates.

Redlich-Kwong corrections affect cold dense gas behavior.

Magnetic fields reduce ablation rates and shape ablation channels.

Abstract

Detailed numerical studies of the ablation of a single neon pellet in the plasma disruption mitigation parameter space have been performed. Simulations were carried out using FronTier, a hydrodynamic and low magnetic Reynolds number MHD code with explicit tracking of material interfaces. FronTier's physics models resolve the pellet surface ablation and the formation of a dense, cold cloud of ablated material, the deposition of energy from hot plasma electrons passing through the ablation cloud, expansion of the ablation cloud along magnetic field lines and the radiation losses. A local thermodynamic equilibrium model based on Saha equations has been used to resolve atomic processes in the cloud and Redlich-Kwong corrections to the ideal gas equation of state for cold and dense gases have been used near the pellet surface. The FronTier pellet code is the next generation of the code described in [R. Samulyak, T. Lu, P. Parks, Nuclear Fusion, (47) 2007, 103--118]. It has been validated against the semi-analytic improved Neutral Gas Shielding model in the 1D spherically symmetric approximation. Main results include quantification of the influence of atomic processes and Redlich-Kwong corrections on the pellet ablation in spherically symmetric approximation and verification of analytic scaling laws in a broad range of pellet and plasma parameters. Using axially symmetric MHD simulations, properties of ablation channels and the reduction of pellet ablation rates in magnetic fields of increasing strength have been studied. While the main emphasis has been given to neon pellets for the plasma disruption mitigation, selected results on deuterium fueling pellets have also been presented.